Open wireless architecture (owa) unified airborne and terrestrial communications architecture

ABSTRACT

This invention relates to an Open Wireless Architecture (OWA) unified airborne and terrestrial communications architecture providing optimal high-speed connections with open radio transmission technologies (RTTs) between aircrafts and ground cells, and between different aircrafts in Ad-Hoc or Mesh network group, to construct the multi-dimensional unified information delivery platform across the airborne networks and the terrestrial networks wherein the same OWA mobile device or OWA mobile computer can be used seamlessly and continuously both in the aircrafts and on the ground.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. patent applicationSer. No. 13/952,609, filed Jul. 27, 2013, and entitled “OPEN WIRELESSARCHITECTURE (OWA) UNIFIED AIRBORNE AND TERRESTRIAL COMMUNICATIONSARCHITECTURE”, which is hereby incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to an Open Wireless Architecture (OWA) UnifiedAirborne and Terrestrial Communications architecture with open radiotransmission technologies between aircrafts and ground cells, andbetween different aircrafts in ad-hoc or mesh network manner to buildthe unified broadband information delivery platform across the airbornenetworks and the terrestrial networks wherein the same OWA mobile devicecan be used seamlessly and continuously both in the aircrafts and on theground.

2. Description of the Related Art

Commercial wireless mobile communications including terrestrial cellularnetwork and airborne network have been developed for long time. However,their architecture remains very closed, especially the airborne networktechnology is still in the earlier dates.

As the ground networking technology is expanding to the space domainwhich is to develop the next generation Internet technology for theground-air infrastructure, a unified airborne and terrestrial networkingsolution becomes the mission-critical demand for everyone in theindustry.

The current airborne communications have the following fatal problems:

-   -   a. Transmission speed is too slow, and both transmission and        system architectures are too closed;    -   b. Too much relying on Satellite communications which are too        expensive to be used in commercial environment;    -   c. It is too difficult to ensure the radio transmission safety        issue for the traditional wireless device used in commercial        aircrafts, and therefore all such wireless devices must be        turned off in the aircrafts;    -   d. Some available non-satellite based transmission technology        for airborne network is very much limited to certain specific        wireless standard only without the capability to support the        overall requirements of the future airborne communications;    -   e. There is no solution available for seamless connections        across the terrestrial networks and the airborne networks.

The above problems exist in the prior arts as follows:

1. Satellite-based Airborne Networks

This technology has been in the industry for about 50 years. However,satellite equipments both in aircrafts and skies are very expensive, andbecause of power issues in the satellite, the transmission speed is mustlimited which is not a cost-effective solution in providing broadbandconnections for users in the aircrafts. In addition, most commercialmobile devices do not support satellite communications except a purelybroadcasting satellite receiver.

Commercial networks require both cost-effective andperformance-efficient solution among the features of transmission speed,mobility handover and network capacity. Satellite network has problemsin cost issue and transmission speed issue, and therefore is notappropriate for commercial applications.

2. Land-Based VHF/UHF Airborne Networks

This solution was proposed in 1960s for the airborne networks. However,VHF (very high frequency) and UHF (Ultra high frequency) are mostly usedfor terrestrial broadcasting (one way) services and there are not enoughtwo-way transceivers on the ground. Furthermore, VHF/UHF has beenalready used by airline industry for airborne radio, navigationinformation and flight information mostly in the form of voice, text,fax and short video, etc. In addition, the transmission speed overVHF/UHF channel is quite limited, and not appropriate for broadbandhigh-speed connections between the aircrafts and the ground.

3. Land-Based CDMA-EVDO Airborne Network

This solution was proposed by Aircell and other companies which use oneCDMA (code division multiplex access) technology to connect theaircrafts with the ground cellular towers. Though the CDMA EVDO(Evolution-Data Optimized) standard has many cellular towers in someregions, this solution has the following two fatal problems:

-   -   a. The transmission is limited to EVDO-CDMA only without being        able to connect to other wireless standards in different regions        or countries without EVDO;    -   b. Because CDMA has many problems in maintaining the high        network capacity and high-speed transmission, etc in the        airborne communication environment, this single solution is hard        to compliment between the network capacity and the transmission        speed in a commercial environment.

Furthermore, in the above solution, there is no transmission safetycontrol scheme in the airborne in-flight connections, and so variouswireless equipments supporting WiMax and PCS, etc are used in theaircrafts which generate a serious radio interference problems with theairborne/aviation navigation and airborne/aviation communicationsystems. Such separate radio transmission technologies in the closedarchitecture without an efficient control will not work at all in thecommercial airborne networks.

4. SDR Based Airborne Network

Software Defined Radio (SDR) technology was used for airborne network in1990s which supports multiple wireless standards in the aircraft-groundconnections. Though it has been used already by the militaryapplications, it has never been used successfully in commercialenvironment, because:

-   -   a. SDR is primarily a radio in which the preset operating        parameters including inter alia frequency range, modulation        type, and/or output power limitations can be reset or altered by        software in order to support different radio frequency bands        and/or standards. Though SDR has been improved a lot to support        re-configurability and flexibility, it is a closed architecture        in coupling different radios into one broadband transceiver. In        other words, SDR consumes much more power and spectrum in        exchange of the system flexibility. From the business point of        view, SDR is not a cost-effective solution in wireless        communications;    -   b. Furthermore, SDR uses broadband transceiver to support        multiple wireless standards which is very expensive in the        commercial environment;    -   c. The SDR device will lose synchronization across the airborne        network and the terrestrial network because of its closed        architecture in both systems and transmissions.

Therefore, this solution is also not appropriate for the commercialairborne networks.

In conclusion, all of these known systems fail to meet one or more ofthe following goals for the airborne network connections:

-   -   a. To provide a cost effective way in securing high-speed        transmission, lossless handover and high network capacity in a        commercial environment;    -   b. To provide a seamless and continuous connection between the        terrestrial network and the in-flight network;    -   c. To support open radio transmission technologies in different        regions and service areas in both aircraft-to-ground and        ground-to-aircraft links;    -   d. To synchronize the mobile device across the airborne network        and the terrestrial network;    -   e. To provide a fully flight-safe connections for the in-flight        wireless network and automatically turn-off the terrestrial        radio transceivers of the mobile devices when in the in-flight        network.

This invention provides a system and method that achieves these goalsvery well.

The present invention is based on a technology called Open WirelessArchitecture (OWA) platform. OWA is different from SDR (software definedradio) as OWA basically maps various wireless standards into openinterface parameters and maintain the system platform including RF,baseband, networks and applications an open architecture. Hence, in OWAsystems, different modules (both hardware and software) can be fromdifferent vendors. It is similar to the open computer architecture inpersonal computer system and open network architecture in packet routersystem.

SDR uses broadband transceiver to support multiple wireless standardswhich is very expensive in the commercial environment. However, OWAconverges multiple air interfaces (or called wireless standards or radiotransmission technologies—RTTs) in an open system platform to maximizethe transmission bandwidth and system performance, but each wirelesstransmission still uses the narrowband transceiver, thereforemaintaining the system in a cost-effective way which is very importantfor the commercial business.

By using OWA technology, we can converge multiple wireless standards inone open system to support both broadband high-speed radio transmissionand seamless fast mobility capability in a mobile fast-fadingpropagation model environment while maintaining the very high mobilenetwork capacity for the commercial mobile business.

In addition, OWA allows allocating multiple air interfaces into anexternal card so that the users can simply change wireless standards byupdating such air interface card without having to change the mobiledevice or mobile terminal system.

Based on the research report (released on Feb. 11, 2010) by BerkeleyWireless Research Center, University of California at Berkeley, threemost important and critical issues in wireless communication terminaldevice are in power & energy, radio spectrum and open wirelessarchitecture (OWA). As long as we have the OWA system, it can helpimprove the energy efficiency and spectrum efficiency greatly. This isextremely important for the future converged networks between theterrestrial network and the airborne network, and between the wirelessaccess network and the mobile cellular network, and further between thewireless network and wireline network.

We will explain in more details in the following sections.

SUMMARY OF THE INVENTION

An object of the invention is to overcome at least some of the drawbacksrelating to the compromise designs of prior art systems and methods asdiscussed above.

In order to solve the problems existed in the conventional airbornecommunications, and meet the goals as discussed, improvement of thecurrent wireless transmission and system architecture is the only andfinal solution. The Open Wireless Architecture (OWA) approach has beenproposed to achieve the above goals and shifted the wireless mobiletechnology from a transmission-specific radio system to aninterface-based open system platform for the complete openness andsimplicity of the future unified wireless terrestrial and airbornecommunications.

This invention discloses a new architecture in converging theterrestrial cellular networks and the airborne communication networksseamlessly and adaptively by utilizing the OWA technology, and enablesan OWA-based mobile device being used continuously and seamlessly inboth the terrestrial networks and the airborne networks with optimaltransmission performance between the aircraft and the ground, and in theairborne in-flight network.

The present invention mainly comprises the following disclosures:

-   -   1. OWA technology allows open radio transmission technologies        (RTTs) for both Up-Link (from ground to aircraft) connection and        Down-Link (from aircraft to ground) connection by implementing        the patented OWA transceiver technology in both OWA.Air        Transceivers in the aircrafts and OWA.Ground Transceivers in the        Ground Cells (or called ground cellular base stations in some        cellular networks). This open RTT approach is very important for        airborne communications because different regions and/or        countries use different RTTs for the terrestrial cellular        networks, and the aircrafts may fly across such different        regions with different RTTs. For example, North America may use        cdma2000 (code division multiplex access) family RTT and/or OFDM        (orthogonal frequency division multiplex) family RTT while Asia        may use TD-SCDMA (time-division synchronized code division        multiplex access) family RTT and/or WCDMA (wideband code        division multiplex access) family RTT for the terrestrial        cellular networks. Even in the same country, different regions        may use different RTTs in terrestrial networks.    -   2. OWA technology allows open radio transmission technologies        (RTTs) for mobile devices or mobile computers to connect to the        available networks seamlessly and continuously both in the        aircrafts and on the ground. The Mobile Users with OWA mobile        devices or computers do not have to turn off their devices or        computers when on board the aircrafts because the OWA.inFlight        protocol will automatically switch the OWA device to the        flight-safe In-Flight mode fully in compliance with the airborne        regulations and guidelines. As long as the aircrafts leave the        airport gate, the In-Flight Pilot signal received by the OWA        mobile device or computer will immediately turn off all the        terrestrial radio transceivers in the device or computer and        switch to the In-Flight mode accordingly before connecting to        the in-flight mobile network fully in compliance with the        airborne regulations.    -   3. OWA technology enables the airborne mobile handover between        the aircraft and the ground cells seamless and lossless because        the airborne navigation information and the ground cells'        information are predictable and well planned in advance, and        hence the aforementioned OWA.Air Transceivers and OWA.Ground        Transceivers can always find the best possible RTT for both the        Up-Link and Down-Link connections well before the handover        occurring. In different regions or same region with different        weather or different situations, the air-ground connections        (Up-Link and/or Down-Link) may need different or multiple RTTs        dynamically or adaptively to optimize the transmission bandwidth        or performance, and therefore OWA technology is the best        solution to fulfill this requirement. Meanwhile, the air-ground        connections may be unbalanced in Up-Link and Down-Link, for        example, if most uses in the aircraft browse the websites        through Internet, the Up-Link traffics are much more than        Down-Link traffics, and in this situation, the aforementioned        OWA.Ground Transceivers need to use high-speed broadband RTT to        connect the aforementioned OWA.Air Transceivers in the Up-Link        channels. In addition, during airborne mobile handover process        and high-speed connection period, but not limited thereto, the        aforementioned OWA.Ground Transceivers will use antenna        beam-forming technology to send strong narrow beams in        connecting the aforementioned OWA.Air Transceivers of the        aircraft for the optimized connections between the aircraft and        the ground cells. The aforementioned OWA.Ground Transceivers        also utilize advanced space-time antenna array technology, etc        to maximize the receiving performance and transmitting        performance for the airborne links, for example, but not limited        thereto, the distributed MIMO (multiple-in multiple-out) with        multiple antennas.    -   4. OWA technology enables same or different radio transmission        technologies (RTTs) in Up-Link and Down-Link, as set forth        above, to maximize the transmission efficiency and performance        in different commercial environments because in some regions the        wireless spectrum availability in either links may be different,        and the available RTTs in either links may also be different.    -   5. OWA technology enables one aircraft to connect to another        aircraft in an Ad-Hoc or Mesh network group through the        aforementioned OWA.Air Transceivers. The Ad-Hoc or Mesh network        group comprises the aircrafts with the shortest distance and/or        slowest speed between each other within certain amount of time,        and this group is updated frequently at certain interval. If any        group aircraft is close to a ground airport, either before        landing or passing by, this aircraft equipped with the        aforementioned OWA.Air Transceivers will connect the Ad-Hoc or        Mesh network to the ground airport to relay or dispatch the        airborne in-flight information and traffics to the ground        network and vice verse. The aforementioned Ad-Hoc or Mesh        network can construct the broadband airborne information        delivery highway among the group aircrafts and build the        cost-effective airborne networks because there are lots of        aircrafts flying in the same flight routes every day across the        country and on the worldwide basis. This solution is very useful        for the airborne network connections especially when the        aircrafts are flying over the ocean where there are no ground        cells available for the ground connection, but there is always        at least one group member aircraft close to an airport in the        same Ad-Hoc or Mesh group, either before landing, after take-off        or passing by. Any OWA.Air Transceiver, as set forth above,        supports multiple RTTs in one system based on OWA technology,        and can adaptively connect to other OWA.Air Transceiver in other        aircraft with optimal RTT connection(s) in different        environments.    -   6. OWA technology enables the Virtual Mobile Server (VMS) on the        ground to synchronize and manage the OWA mobile devices or        computers, as set forth above, between the terrestrial mode and        the in-flight mode when mobile users travel across airborne        networks and terrestrial networks, and to support OWA Mobile        Cloud architecture so that many processing tasks and/or modules        can be moved from the OWA mobile devices or computers to the OWA        VMS, as set forth above. This is important to make the future        mobile device or mobile notebook simple to use and simple to        operate, and optimize its transmission and system performance        including power efficiency, spectrum efficiency and cost        effectiveness.    -   7. OWA technology enables the OWA mobile devices or mobile        notebooks connecting to the OWA.onBoard wireless router and        access point in a flight-safe In-Flight wireless network        supporting these safe in-flight RTTs:        -   a. Standard wireless local area network (WLAN) with reduced            and lowest possible transmitting power for airborne            in-flight connection, fully monitored and controlled at all            times by the aforementioned OWA.onBoard Wireless Router and            Access Point to avoid any frequency interference with any            aviation communication and navigation systems,        -   b. Modified wireless local area network for airborne            in-flight connection (WLAN.Air) which is completely in            compliance with the airborne communication regulations and            guidelines,        -   c. Standard wireless personal access network or personal            area network (WPAN) with reduced and lowest possible            transmitting power for airborne in-flight connection, fully            monitored and controlled at all times by the aforementioned            OWA.onBoard Wireless Router and Access Point to avoid any            frequency interference with any aviation communication and            navigation systems, and        -   d. Modified wireless personal access network for airborne            in-flight connection (WPAN.Air) which is completely in            compliance with the airborne communication regulations and            guidelines.

The search order of the connection modes between the OWA.inFlight MobileDevice/Notebook (same aforementioned OWA mobile device or notebook inthe in-flight mode) and the OWA.onBoard Wireless Router and AccessPoint, as set forth above, can be re-configured or re-set by the mobileusers or the aircrafts. By default, the search order is by WLAN.Air,WPAN.Air, WLAN, WPAN, Wireline.

The aforementioned OWA.onBoard Wireless Router and Access Point managesand monitors the aforementioned flight-safe RTTs to ensure there is nofrequency interference with the aircraft/aviation communication andnavigation systems.

The aforementioned OWA.Air Transceivers can also connect to broadbandSatellite networks for Internet access.

The aforementioned OWA Mobile Devices include new OWA mobile devices andOWA-enabled existing mobile devices.

The OWA-enabled Mobile Device is an existing mobile device with externalOWA module attached to the existing mobile device wherein the externalOWA module facilitates completely switching from the terrestrial mode tothe in-flight mode by the In-Flight Pilot Signal, and completely turningoff the terrestrial radio transceiver in the in-flight mode, and theexternal OWA module further enables the existing mobile device to fullysupport the In-Flight RTTs including the WLAN.Air, the WPAN.Air, theWLAN and the WPAN.

The external OWA module can be in the form of memory card, USB(Universal Serial Bus) card, any portable interface card, or beingembedded in or integrated into a protection case of the existing mobiledevice.

The external OWA module has functions of turning off terrestrialcellular radio transceiver of the existing mobile device and controllingtransceivers of WLAN and WPAN in the existing mobile device to meetsystem requirements of the In-Flight RTTs including the WLAN.Air, theWPAN.Air, the WLAN and the WPAN.

A Virtual Mobile Server onBoard Server (VMS.onBoard Server) is anin-flight mobile cloud server for the OWA mobile devices or OWA-enabledmobile devices of the in-flight wireless networks. The VMS.onBoardServer connects to OWA.VMS main server via the OWA.Air Transceivers.

The in-flight users can push interesting applications, services andcontents to the VMS.onBoard Server for sharing with other the users, andthe users can pop interesting applications, services and contents sharedby other the users from the VMS.onBoard Server.

The VMS.onBoard Server is an in-flight mobile cloud server, extendedfrom the OWA.VMS which is a main mobile cloud server on ground.

Therefore, the in-flight Internet access includes connections to thebroadband Satellite networks, the ground networks, the airport networksand/or the Ad-Hoc/Mesh network group via the aforementioned OWA-AirTransceivers.

Based on our long-time research on wireless transmissions and seamlessmobility management, no SINGLE wireless standard (or call radiotransmission technology—RTT) can support both broadband high-speedtransmission and seamless mobility in a commercial environment, andtherefore the broadband transmission, seamless mobility and networkcapacity are the three contradictory elements in a SINGLE wireless RTTof commercial environment. To meet all these three requirements, we needto converge multiple wireless standards (or RTTs) on an open platform inboth transmission level and system level, and therefore, the OpenWireless Architecture (OWA) technology was proposed and developed.

The OWA technology is extremely important for the unified terrestrialand airborne communications in terms of spectrum efficiency,transmission efficiency, energy efficiency, performance efficiency aswell as cost-effectiveness in a commercial environment.

The details of the present invention are disclosed in the followingdrawings, descriptions as well as the claims based on the abovementionedelements.

The various aspects, features and advantages of the disclosure willbecome more fully apparent to those having ordinary skill in the artupon careful consideration of the following detailed description thereofwith the accompanying drawings described below.

BRIEF DESCRIPTION OF THE DRAWINGS

For the full understanding of the nature of the present invention,reference should be made to the following detailed descriptions with theaccompanying drawings in which:

FIG. 1 is an Open Wireless Architecture (OWA) Unified Airborne Network(AirNet) Infrastructure,

FIG. 2 is a detailed AirNet Architecture based on OWA technology,

FIG. 3 introduces the OWA.inFlight Mobile Network in the aircraftcabins,

FIG. 4 discloses the OWA.inFlight Mobile Access Control method, and

FIG. 5 describes the detailed OWA.Air Connection Control method for theairborne networks.

FIG. 6 shows a method to optimize in-flight wireless networks andservices based on open wireless architecture (OWA) mobile cloudinfrastructure.

Like reference numerals refer to like parts throughout the several viewsof the drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The present inventions now will be described more fully hereinafter withreference to the accompanying drawings, in which some examples of theembodiments of the inventions are shown. Indeed, these inventions may beembodied in many different forms and should not be construed as limitedto the embodiments set forth herein; rather, these embodiments areprovided by way of example so that this disclosure will satisfyapplicable legal requirements. Like numbers refer to like elementsthroughout.

The present invention relates to an Open Wireless Architecture (OWA)unified airborne and terrestrial communication networks providingoptimal high-speed connections with open radio transmission technologies(RTTs) between aircrafts and ground cells, and between differentaircrafts in Ad-Hoc or Mesh group, to construct the multi-dimensionalunified information delivery platform across the airborne networks andthe terrestrial networks wherein the same OWA mobile device or OWAmobile computer can be used seamlessly and continuously both in theaircrafts and on the ground.

FIG. 1 describes the Open Wireless Architecture (OWA) Unified Airborneand Terrestrial Networking Infrastructure. The airborne connections havetwo different ways:

The moving aircrafts, equipped with OWA.Air Transceivers, connect to theGround Cell towers with OWA.Ground Transceivers through the AirborneMobile Handover protocol. Since the aircraft navigation routes arepredictable and pre-loaded in the airborne system, and the ground cells'information is also known in advance, this airborne mobile handover isactually well planned when in flight.

Furthermore, because the airborne handover is fully predictable, theassociated ground cells of handover will be able to form the narrowantenna beams well in advance and prepare for handover in an optimal wayto maximize the transmission throughput.

In addition, the aircrafts may use space-time technologies of multipleantennas to connect the ground cells for the high-speed broadbandtransmission. OWA technology allows open radio transmission technologiesbetween the ground cells and the aircrafts so that the Up-Link (fromground to aircraft) and Down-Link (from aircraft to ground) connectionsare always optimized.

The moving aircraft, equipped with aforementioned OWA.Air Transceivers,connects to other moving aircraft with aforementioned OWA.AirTransceivers in an Ad-Hoc or Mesh network topology, to construct thebroadband high-speed transmission channels as the Over-the-AirInformation Delivery and Relay Platform.

The Ad-Hoc or Mesh group comprises the aircrafts with the shortestdistance and/or slowest speed between each other within certain amountof time, and the group is updated frequently at certain interval.

If the moving aircraft is close to a ground airport, either aftertake-off, before landing or passing by, this moving aircraft, equippedwith the aforementioned OWA.Air Transceiver, further connects to theassigned ground airport by separate OWA aircraft-ground links, toconnect the Ad-Hoc or Mesh network with the ground backbone network anddispatch the airborne traffics to the ground network, and vice verse.

Again, OWA technology allows open radio transmission technologiesbetween the moving aircrafts of the Ad-Hoc or Mesh group, and betweenthe moving aircraft and its assigned ground airport, to maximize thebroadband high-speed transmissions over the Air Link.

By utilizing the above integrated high-speed transmissions, the unifiedair networks (called AirNet) are established, and the bandwidth of theaircrafts with the aforementioned OWA.Air Transceivers can be optimized.

The Broadcast Satellite, though not required for this OWA unifiedAirNet, can be helpful in updating the ground cells information, groundairports information and the airborne navigation routing information,etc. But the broadband Satellite networks are also connected to theaforementioned in-flight network via the OWA.Air Transceiver(s).

The ground Virtual Mobile Server (VMS) is utilized to support the OWAMobile Cloud infrastructure where any mobile users' information in theAirNet can be synchronized in this VMS. In addition, many processingtasks including signal processing and application processing can be donein this VMS as well. Besides the main VMS server on ground, there is asub VMS server on-board in the aircraft, connected by the OWA.AirTransceiver(s) in the aircraft.

Both OWA.Air transceivers and OWA.Ground transceivers, as set forthabove, support open radio transmission technologies (RTTs) in aspectrum-efficient, bandwidth-optimal and cost-effective way, whereinthe RTTs include Code Division Multiplex Access (CDMA), Time DivisionMultiplex Access (TDMA), OFDMA (Orthogonal Frequency Division MultiplexAccess), SDMA (Space Division Multiplex Access) and their combinations,etc, but not limited thereto.

FIG. 2 illustrates the detailed AirNet architecture based on OWAtechnology. The aforementioned OWA.Air Transceivers in the aircrafts cannot only connect to the aforementioned Ground Cells with aforementionedOWA.Ground Transceivers, but also connect to other aircrafts in Ad-Hocor Mesh network mode. Hence, each aircraft has multiple aforementionedOWA.Air Transceivers installed for such multi-dimensional AirNetconnections.

Inside the aircraft cabins, the information received by aforementionedOWA.Air Transceivers from the aforementioned Ground Cells or Ad-Hoc/Meshnetwork will be routed to the in-flight mobile users (in-flightPassengers) through the OWA.onBoard Wireless Router and Access point,and vice verse.

The aforementioned OWA.Air Transceivers in the aircrafts support openradio transmission technologies (RTTs) in a spectrum-efficient andbandwidth-optimized way, wherein the RTTs include Code DivisionMultiplex Access (CDMA), Time Division Multiplex Access (TDMA), OFDMA(Orthogonal Frequency Division Multiplex Access), SDMA (Space DivisionMultiplex Access) and their combinations, but not limited thereto. Theaforementioned OWA.Air Transceivers can also enable different RTTs inthe Up-Link (from ground to aircrafts) and Down-Link (from aircrafts toground) channels subject to spectrum, service and specific transmissionrequirements, but not limited thereto.

The aforementioned OWA.onBoard Wireless Router and Access Point supportthe low-power and flight-safe wireless local area network (WLAN) and/orwireless personal access network (or called personal area network)(WPAN) so that the in-flight mobile users can access to the OWA.onBoardWireless Router and Access Point, as set forth above, wirelessly andseamlessly inside the aircraft cabins. The aforementioned in-flightwireless network by aforementioned WLAN and/or WPAN is fully controlledand monitored by aforementioned OWA.onBoard Wireless Router and AccessPoint to avoid any frequency interference with any aviationcommunication and navigation systems.

The Up-Link from the Ground Cells to the Aircrafts is a broadbandhigh-speed link wherein the Ground Cells' Transceivers, as set forthabove, form the narrow beams adaptively with strong transmitting powersand directional antennas (or antennas array) to connect to theassociated OWA.Air Transceivers, as set forth above, to construct thevery high-speed transmission link. In comparison, the Down-Link from theAircrafts to the Ground Cells is a regular transmission link becausemost of the transmission traffics are in the Up-Link direction.

In order to increase the transmission bandwidth and optimize the linkperformance in both directions (Up-Link and Down-Link), many Space-Timetransmission processing technologies (such as Multiple-In Multiple-Out,but not limited thereto) can be utilized in both the OWA.AirTransceivers and the OWA.Ground Transceivers, as set forth above.

The Airborne mobile handover among multiple Ground Cells is based onpreloaded navigation routing information and Ground Cells information,and therefore, the aforementioned airborne connection handover ispredictable and well planned. This kind of predictable and on-schedulehandover can optimize the AirNet connections more effectively and morestably.

The Broadcast Satellite can help broadcast useful Ground information andnavigation information, etc for the Airborne networks (AirNet), and helpadjust the Airborne Mobile Handover protocol as well as update theAd-Hoc or Mesh network information with other aircrafts in the sameAirborne Group.

The OWA.Ground Transceiver, as set forth above, is a modifiedterrestrial cellular transceiver system based on OWA platform which cansupport any cellular radio transmission technology (RTT) including CDMA,TDMA, OFDMA and SDMA, etc, as set forth above. The aforementionedOWA.Ground Transceivers are equipped with Beam-forming technologiesand/or advanced antenna array technologies to generate the strong narrowbeams in connecting the airborne OWA.Air Transceivers, as set forthabove, to construct the aforementioned broadband high-speed Up-Link.

In the regular Down-Link from the OWA.Air Transceivers to the OWA.GroundTransceivers, as set forth above, the aforementioned OWA.GroundTransceiver increases its receiving sensibility by utilizing space-timereceiving technologies such as antenna array or distributed MIMO(multiple-in multiple-out) with multiple antennas, but not limitedthereto, and maximize its receiving performance across one or multipleOWA.Ground Transceivers, as set forth above.

Because both the Up-Link and the Down-Link use the patented OWAtransceiver technology (U.S. Pat. No. 7,522,888, Application No.20080146178 and so on, etc), the AirNet wireless transmissionperformance can be optimized and the spectrum efficiency is thereforemaximized, especially for the future open spectrum management strategyas well as spectrum sharing, spectrum sensing and/or spectrum recyclingstrategies.

Based on our long-time research on wireless transmissions and seamlessmobility management, no SINGLE wireless standard (or call radiotransmission technology—RTT) can support both broadband high-speedtransmission and seamless mobility in a commercial environment, andtherefore the broadband transmission, seamless mobility and networkcapacity are the three contradictory elements in a SINGLE wireless RTTof commercial environment. To meet all these three requirements, we needto converge multiple wireless standards (or RTTs) on an open platform inboth transmission level and system level, and therefore, the OpenWireless Architecture (OWA) technology was proposed and developed.

In a commercial AirNet environment, the wireless transmission linkbetween the aircraft and the ground cell is very high-speed, and theaircrafts move very fast.

Furthermore, the aircrafts may fly over many different regions withdifferent RTTs (or wireless standards) in the terrestrial cellularnetworks. Hence, the OWA technology is the best solution to convergevarious RTTs in an optimal way for the best wireless connections betweenthe Aircrafts and the Ground Cells, as set forth above, to construct theopen AirNet architecture which can be applied in any commercial airbornecommunication environment.

FIG. 3 introduces an OWA-based In-Flight Mobile Network which comprisesthe following:

-   -   1. OWA.onBoard Wireless Router and Access Point, the on-board        wireless base station and wireless router to connect and manage        the In-Flight mobile handheld devices and mobile notebooks        through the wireless channels. The OWA.onBoard Wireless Router        and Access Point, as set forth above, connects to the        aforementioned OWA.Air Transceiver of the aircraft which further        connecting to the Ground Cells or other Aircrafts in Ad-Hoc or        Mesh network.    -   2. OWA.inFlight Mobile Device supporting both terrestrial and        In-Flight communication modes based on OWA platform. Whenever        the OWA Mobile Device receives the In-Flight Pilot Signal of the        aircraft, it automatically turned off the terrestrial radio        transceivers, and switch to the In-Flight mode immediately. The        aforementioned OWA.inFlight Mobile Device then connects to the        OWA.onBoard Wireless Router and Access Point, as set forth        above, to establish the in-flight broadband connections. In the        same or similar way, the OWA.inFlight Mobile Notebooks connect        to the aforementioned OWA.onBoard Wireless Router and Access        Point for the in-flight broadband wireless connections.    -   3. OWA.Air Transceiver and onboard Server caching the In-Flight        users' information and forwarding the In-Flight broadband        information and traffics to the Ground Networks or other        Aircrafts in the Ad-Hoc or Mesh network, as set forth above.

The OWA.onBoard Wireless Router and Access Point, as set forth above,supports the following radio transmission technologies (RTTs):

-   -   1. Standard wireless local area network (WLAN) with reduced and        lowest transmitting power for in-flight application;    -   2. Modified wireless local area network for Airborne        applications (WLAN.Air) which is completely in compliance with        the airborne communication regulations and guidelines;    -   3. Standard wireless personal access network (WPAN) with reduced        and lowest transmitting power for in-flight applications;    -   4. Modified wireless personal access network for Airborne        applications (WPAN.Air) which is completely in compliance with        the airborne communication regulations and guidelines.

When the aforementioned OWA.inFlight Mobile Device or Mobile Notebook isin In-Flight mode, it performs the following tasks immediately:

-   -   1. All terrestrial radio transceivers in the OWA.inFlight Mobile        Device and/or Mobile Notebook are turned OFF automatically;    -   2. OWA.inFlight Mobile Device and/or Mobile Notebook is        connected to OWA.onBoard Wireless Router and Access Point;    -   3. OWA.inFlight Mobile Device and/or Mobile Notebook are        synchronized to the OWA Mobile Cloud VMS (Virtual Mobile Server)        on the Ground. The aforementioned VMS is utilized to be the        virtual secretary for the mobile users in both the terrestrial        and the in-flight applications based on the OWA technology        platform, and multiple OWA mobile devices can share the same VMS        on the Ground, as set forth above.

During In-Flight mode, the aforementioned OWA.inFlight Mobile Device canpush any information to the aforementioned VMS, or retrieve anyinformation from the aforementioned VMS. In this way, the OWA mobiledevice is fully synchronized between the terrestrial mode and thein-flight mode when the mobile users travel across the airborne networksand the terrestrial networks.

By using OWA Mobile Device of unified terrestrial and in-flight modes,the mobile users can continue seamless communications from the Groundnetworks to the Airborne networks, and from the Airborne networks to theGround networks. Furthermore, the OWA.inFlight Mobile Device, as setforth above, is in full compliance with the airborne regulations onsafety and security, and the users (or passengers) do not have to turnoff the mobile devices when on board the aircrafts.

As mobile device becomes the most important communication andinformation equipment on the worldwide basis, the aforementioned unifiedterrestrial and in-flight OWA mobile device will drive this futuredirection in delivering the truly service-oriented information to themobile users anywhere, anytime and with anyone.

FIG. 4 discloses the access control method of the OWA.inFlight MobileDevice in the aircraft of the Airborne network.

After the users get on board in the aircraft, and the aircraft getsready for takeoff or in flight (or by some airborne regulations, as longas the aircraft leaves the airport Gate), an In-Flight Pilot Signal willbe broadcasted to all the OWA mobile devices or mobile notebooks in theaircraft cabins.

If the OWA Mobile Device does not receive the aforementioned In-FlightPilot Signal, it remains in the Terrestrial mode with the Groundcellular networks. Otherwise, the aforementioned OWA Mobile Deviceimmediately turns off all the terrestrial radio transceivers of thedevice, and switch to the In-Flight Mode accordingly.

When in the In-Flight mode, the aforementioned OWA.inFlight MobileDevice checks whether the WLAN.Air radio transmission technology (RTT),as set forth above, is available for the in-flight connection. Ifavailable, the aforementioned OWA.inFlight Mobile Device is set in theaforementioned WLAN.Air connection mode, otherwise, it further checkswhether the WPAN.Air radio transmission technology (RTT), as set forthabove, is available for the in-flight connection. If available, theaforementioned OWA.inFlight Mobile Device is set in the aforementionedWPAN.Air connection mode.

If both the WLAN.Air and WPAN.Air RTTs, as set forth above, are notavailable for the in-flight connection, the aforementioned OWA.inFlightMobile Device further searches the standard WLAN radio transmissiontechnology (RTT) or standard WPAN radio transmission technology (RTT).If either of them is available, the aforementioned OWA.inFlight MobileDevice first reduces its radio transmitting power of the aforementionedRTT to the minimal level, then connects to the OWA.onBoard WirelessRouter and Access Point, as set forth above, in the aforementioned RTTconnection mode.

If all the WLAN.Air, WPAN.Air, WLAN, WPAN RTTs, as set forth above, arenot available for the in-flight connection, the aforementionedOWA.inFlight Mobile Device also supports the wireline connection mode byplugging into the OWA.onBoard Wireless Router and Access Point, as setforth above, through a networking cable or other forms of wiring in theaircraft.

If all of the aforementioned connections are failed, the aforementionedOWA.inFlight Mobile Device will restart the access control again fromthe beginning.

It is emphasized that, as long as the aircraft leaves the airport Gate(in flight, taxing, taking-off, landing), the In-Flight Pilot Signal, asset forth above, remains ON and continues broadcasting to all the OWAmobile devices or mobile notebooks in the aircraft cabins. Therefore,the aforementioned OWA.inFlight Mobile Device maintains in the In-FlightMode all the time.

Only after the aircraft returns back and stop completely to the airportGate, the aforementioned In-Flight Pilot Signal can be turned off, andso the aforementioned OWA.inFlight Mobile Device can be switched back tothe Terrestrial mode for the ground cellular networks.

Based on different airborne regulations and rulings in differentregions, the time to release or turn-off the aforementioned In-FlightPilot Signal may vary. However, for airborne safety consideration, westrongly suggest to turn off the aforementioned In-Flight Pilot Signalafter completely returning to the airport gate.

The search order of the connection modes between the OWA.inFlight MobileDevice and the OWA.onBoard Wireless Router and Access Point, as setforth above, can be re-configured or re-set by the mobile users or theaircrafts. By default, the search order is by WLAN.Air, WPAN.Air, WLAN,WPAN, Wireline, as set forth above.

The aforementioned WLAN.Air and WPAN.Air are the completely safest modesfor the In-Flight connection. The aforementioned WLAN and WPAN modesmust turn the radio transmitting power to be the lowest possible incompliance with the airborne regulations, and must be fully monitored atall times for the In-Flight connection.

The aforementioned OWA.onBoard Wireless Router and Access Point managesand monitors the aforementioned flight-safe RTTs to ensure there is nofrequency interference with the aircraft communication and navigationsystems.

The aforementioned In-Flight Pilot Signal is broadcasted to the OWAMobile Device through a separate broadcasting channel by certainshort-distance radio broadcasting technology in the airborne cabins oraircrafts.

FIG. 5 discloses the OWA.Air Connection Control for the Airbornecommunication networks. There are two different OWA.Air connectionmethods:

1. Connection Between OWA.Air and OWA.Ground

The aforementioned OWA.Air (OWA.Air Transceiver and its controller)loads the aircraft navigation routing information and the Ground Cellsinformation. Then, the aforementioned OWA.Air detects the current andnext Ground Cells for the airborne mobility handover control based onthe detection of signal strengths received from the Ground Cells and theupdated Ground Cells' sequence by pre-loaded or updated Ground Cellsinformation. When the moving aircraft is ready for handover, theaforementioned OWA.Air transceivers connect and handover among thedetected Ground Cells accordingly. After this handover is completed, theaforementioned OWA.Air updates the Ground Cells information for the nexthandover to come, and repeats the above steps again.

Because the airborne mobility handover is predictable and fullyon-schedule, both the Up-Link (from ground to aircraft) and Down-Link(from aircraft to ground) connections of the Airborne Networks can beseamless and lossless during the handover period.

Furthermore, by utilizing advanced space-time transmitting and receivingtechnologies (such as space diversity, antenna arrays, smart antennasand Multiple-In Multiple-Out antenna technologies, but not limitedthereto) in OWA.Air Transceivers and/or OWA.Ground Transceivers, as setforth above, the aforementioned Up-Link and Down-Link connectionbandwidth can be maximized and optimized which absolutely improves theairborne network performance.

Furthermore, the OWA.Ground Transceivers, as set forth above, activelyand adaptively send strong narrow beams to the associated OWA.AirTransceivers, as set forth above, based on the advanced antennabeam-forming technology, to ensure the broadband high-speed connectionsin the aforementioned Up-Link channels.

Again, OWA technology allows open radio transmission technologiesbetween the ground cells and the aircrafts so that the Up-Link (fromground to aircraft) and Down-Link (from aircraft to ground) are alwaysoptimized.

Further, OWA technology enables same or different radio transmissiontechnologies (RTTs) in Up-Link and Down-Link, as set forth above, tomaximize the transmission efficiency and performance in differentcommercial environments because in some regions the wireless spectrumavailability in each link may be different, and the available RTTs ineach link may also be different, but not limited thereto.

In addition, in order to combat and overcome the Doppler effect (orDoppler shift) and/or transmission delay for the fast moving aircrafts,the aforementioned OWA.Ground Transceivers can perform additionaltransmission processing by using antenna calibration technology and/orsignal processing technology on the ground.

2. Connection Between OWA.Air and OWA.Air in Different Aircrafts

The aforementioned OWA.Air (OWA.Air Transceiver and its controller) inone aircraft loads the Airborne Group (Ad-Hoc or Mesh network Group)information and the Ground Airports information, where theaforementioned Airborne Group comprises the aircrafts with the shortestdistance and/or slowest speed between each other within certain amountof time, and the group is updated frequently at certain interval.

The aforementioned OWA.Air in one aircraft then requests theaforementioned Group member(s) for Ad-Hoc network connection or meshnetwork connection based on the different airborne networks topology indifferent regions. The aforementioned OWA.Air keeps sending such requestuntil it is accepted by one new Group Member, as set forth above.

Then, the aforementioned OWA.Air in one aircraft connects theaforementioned new Group Member for Ad-Hoc or Mesh network connection.

If the moving aircraft is close to a ground airport, either aftertake-off, before landing or passing by, this moving aircraft, equippedwith the aforementioned OWA.Air Transceiver, further connects to theassigned ground airport by separate OWA aircraft-ground links, toconnect the Ad-Hoc or Mesh network with the ground backbone network anddispatch the airborne traffics to the ground network, and vice verse.

Again, OWA technology allows open radio transmission technologiesbetween the moving aircrafts of the Ad-Hoc or Mesh group, and betweenthe moving aircraft and its assigned ground airport, to maximize thebroadband high-speed transmissions over the Air Link.

The aforementioned airborne Ad-Hoc or Mesh networks with OWA.AirTransceivers, as set forth above, provide an optimal way to constructthe Over-the-Air high-speed information delivery and information relayplatform for the airborne communication networks which can also beutilized to build the next generation network or Internet technologyfully converging the terrestrial and airborne communication networks inan open and unified infrastructure.

The OWA.Air Transceivers can also connect to broadband Satellitenetworks for Internet access.

By utilizing the aforementioned integrated high-speed transmissions withdifferent network topology, the unified airborne networks (calledAirNet) are established, and the connection bandwidth of the aircraftswith the ground backbone network can be optimized.

FIG. 6 shows an improved method to optimize the in-flight wirelessnetworks for best-of-effort Internet access for in-flight mobile users.

A method to optimize in-flight wireless networks and services based onopen wireless architecture (OWA) mobile cloud infrastructure comprisesthe following steps:

-   -   a) connecting OWA Mobile Device or OWA-enabled Mobile Device to        OWA.onBoard Wireless Router which is an in-flight wireless        router or access point, through OWA.onBoard RTTs (radio        transmission technology) which is In-Flight RTTs,    -   b) connecting the OWA.onBoard Wireless Router to Virtual Mobile        Server onBoard Server (VMS.onBoard Server) which is an in-flight        mobile cloud server),    -   c) synchronizing the VMS.onBoard Server with OWA.VMS on Ground        (main Mobile Cloud Server) whenever wireless connection is        available, via OWA.Air Transceiver(s) in aircraft,    -   d) offering best-of-effort in-flight applications and services        to users of in-flight community through the in-flight wireless        networks, and    -   wherein, the OWA.onBoard Wireless Router is turned ON or OFF by        In-Flight Pilot Signal, and the OWA.onBoard Wireless Router is        optimized by OWA RTT Optimization.

The OWA.onBoard RTTs or the In-Flight RTTs comprise:

-   -   a) standard wireless local area network (WLAN) with reduced and        lowest possible transmitting power for airborne in-flight        connection, fully monitored and controlled at all times by the        OWA.onBoard Wireless Router to avoid frequency interference with        any aviation communication and navigation systems,    -   b) modified wireless local area network for airborne in-flight        connection (WLAN.Air) which is completely in compliance with the        airborne communication regulations and guidelines,    -   c) standard wireless personal access network or personal area        network (WPAN) with reduced and lowest possible transmitting        power for airborne in-flight connection, fully monitored and        controlled at all times by the OWA.onBoard Wireless Router to        avoid frequency interference with any aviation communication and        navigation systems, and    -   d) modified wireless personal access network or personal area        network for airborne in-flight connection (WPAN.Air) which is        completely in compliance with the airborne communication        regulations and guidelines.

The OWA Mobile Device (or OWA-enabled Mobile Device) connecting to theOWA.onBoard Wireless Router for In-Flight mode comprises:

-   -   a) the OWA Mobile Device immediately turning off all of its        terrestrial radio transceivers and switching to the In-Flight        mode automatically when receiving an In-Flight Pilot Signal of        the aircraft through a separate in-flight broadcasting channel        in the aircraft cabins,    -   b) the OWA Mobile Device being connected to the OWA.onBoard        Wireless Router through the In-Flight RTTs, and    -   c) the OWA Mobile Device being synchronized to the VMS.onBoard        Server, and being able to push any information, contents or        applications to the VMS.onBoard Server or retrieve any        information, contents or applications from the VMS.onBoard        Server.

The OWA RTT Optimization comprises:

-   -   a) the OWA Mobile Device (or OWA-enabled Mobile Device)        remaining in Terrestrial mode with Ground networks if the OWA        Mobile Device not receiving the In-Flight Pilot Signal in        aircraft cabins,    -   b) the OWA Mobile Device immediately turning off its terrestrial        radio transceivers, switching to the In-Flight Mode accordingly        after receiving the In-Flight Pilot Signal in aircraft cabins,        and the OWA Mobile Device becoming an OWA.inFlight Mobile Device        for in-flight wireless connection,    -   c) the OWA Mobile Device searching whether the WLAN.Air RTT is        available for the in-flight wireless networks, and the OWA        Mobile Device being connected in the WLAN.Air connection mode if        the WLAN.Air RTT is available, otherwise, the OWA Mobile Device        further searching whether the WPAN.Air RTT is available for the        in-flight wireless networks, and the OWA Mobile Device being        connected in the WPAN.Air connection mode if the WPAN.Air RTT is        available,    -   d) the OWA Mobile Device further searching the WLAN RTT or the        WPAN RTT if both the WLAN.Air RTT and the WPAN.Air RTT are not        available for the in-flight wireless networks, and the OWA        Mobile Device first reducing its radio transmitting power to the        minimal level, then connecting to the in-flight wireless        networks in the WLAN or the WPAN connection mode if either the        WLAN RTT or the WPAN RTT is available, and    -   e) the OWA Mobile Device also supporting wireline connection        mode by plugging into the OWA.onBoard Wireless Router through a        networking cable or other forms of wiring in the aircraft.

Search order of connection modes between the OWA Mobile Device and theOWA.onBoard Wireless Router is re-configured or re-set by mobile usersor aircrafts wherein by default, the search order is by the WLAN.Air,the WPAN.Air, the WLAN, the WPAN and the wireline connection.

The WLAN.Air and the WPAN.Air are the safest modes for In-Flightconnection, networking and services, completely in compliance withairborne communication regulations and guidelines.

The OWA.Air Transceiver connects to Ground Cell(s) of Ground Networks,other the OWA.Air Transceiver in Ad-Hoc or mesh network group, BroadbandSatellite Networks, and/or Ground Airport Networks for Internet Access.

The in-flight community includes passengers of same flight andneighborhood flights of same the Ad-Hoc or mesh network group.

The users can push interesting applications, services and contents tothe VMS.onBoard Server for sharing with other the users, and the userscan pop interesting applications, services and contents shared by otherthe users from the VMS.onBoard Server.

The VMS.onBoard Server is an in-flight mobile cloud server, extendedfrom the OWA.VMS which is a main mobile cloud server on ground.

The in-flight applications and services comprise:

-   -   a) in-flight social networking,    -   b) in-flight video sharing,    -   c) in-flight business conferencing,    -   d) in-flight interactive gaming,    -   e) in-flight shopping mall,    -   f) in-flight audio and video library,    -   g) in-flight safety and security,    -   h) in-flight VIP (very important person) services, and        wherein, the in-flight social networking service and application        includes displaying and updating of elements of passenger's        photo, seat number, nickname and content windows comprising        messaging, posting, pictures and videos, as well as linking to        or synchronizing with passenger's terrestrial social networking        platforms including Facebook, LinkedIN and Google plus.

The OWA-enabled Mobile Device is an existing mobile device with externalOWA module attached to the existing mobile device wherein the externalOWA module facilitates completely switching from the terrestrial mode tothe in-flight mode by the In-Flight Pilot Signal, and completely turningoff the terrestrial radio transceiver in the in-flight mode, and theexternal OWA module further enables the existing mobile device to fullysupport the In-Flight RTTs including the WLAN.Air, the WPAN.Air, theWLAN and the WPAN.

The In-Flight Pilot Signal remains ON and continues broadcasting to allthe OWA Mobile Devices in the aircraft cabins to maintain the In-Flightmode as long as the aircraft leaves airport Gate (in flight, taxing,taking-off, landing), and the In-Flight Pilot Signal can be turned offonly after the aircraft returns to and stops completely at airport Gateto enable the OWA Mobile Device switch back to the Terrestrial Mode withthe ground network, wherein the time to release or turn-off theIn-Flight Pilot Signal may vary based on different airborne regulationsand rulings in different regions, and in most situations, the In-FlightPilot Signal is turned off only after the aircrafts return to AirportGates.

The In-Flight Pilot Signal will automatically switch the OWA MobileDevice from the Terrestrial mode to the In-Flight mode completely, sothat the OWA Mobile Device does not have to power off or manually switchto the in-flight mode when on board the aircrafts.

The VMS.onBoard Server is also utilized to be a virtual secretary formobile user with the OWA Mobile Device in the In-Flight mode, andmultiple the OWA Mobile Devices can share same the VMS.onBoard Server.

The OWA Mobile Device allows allocating multiple air interfaces into anexternal air interface card and mobile users change wireless standardsby updating the air interface card without having to change the OWAmobile device.

Each OWA.Air Transceiver is capable to support one or multipleconnections to either the OWA.Ground Transceiver, the ground network,the ground airport network, the broadband Satellite network, or to otherthe OWA.Air Transceiver in other aircraft of the ad-hoc or mesh networkgroup.

Each aircraft is equipped with one or multiple the OWA.Air Transceiversfor constructing broadband unified airborne and terrestrial networks forhigh-quality in-flight applications and services.

The external OWA module can be in the form of memory card, USB(Universal Serial Bus) card, any portable interface card, or beingembedded in or integrated into a protection case of the existing mobiledevice.

The external OWA module has functions of turning off terrestrialcellular radio transceiver of the existing mobile device and controllingtransceivers of WLAN and WPAN in the existing mobile device to meetsystem requirements of the In-Flight RTTs including the WLAN.Air, theWPAN.Air, the WLAN and the WPAN.

The In-Flight Pilot Signal is utilized to control the users' radiotransceivers and the In-Flight RTTs for the OWA mobile devices, theOWA-enabled mobile devices and the OWA.onBoard wireless router, as setforth above.

Since many modifications, variations and changes in detail can be madeto the described preferred embodiment of the invention, it is intendedthat all matters in the foregoing description and shown in theaccompanying drawings be interpreted as illustrative and not in alimiting sense. Thus, the scope of the invention should be determined bythe appended claims and their legal equivalents.

Furthermore, many modifications and other embodiments of the inventionsset forth herein will come to mind to one skilled in the art to whichthese inventions pertain having the benefit of the teachings presentedin the foregoing descriptions and the associated drawings. Therefore, itis to be understood that the inventions are not to be limited to thespecific examples of the embodiments disclosed and that modificationsand other embodiments are intended to be included within the scope ofthe appended claims. Although specific terms are employed herein, theyare used in a generic and descriptive sense only and not for purposes oflimitation.

What is claimed:
 1. A method to optimize in-flight wireless networks andservices based on open wireless architecture (OWA) mobile cloudinfrastructure, said method comprising: a) connecting OWA Mobile Deviceor OWA-enabled Mobile Device to OWA.onBoard Wireless Router which is anin-flight wireless router or access point, through OWA.onBoard RTTs(radio transmission technology) which is In-Flight RTTs, b) connectingsaid OWA.onBoard Wireless Router to Virtual Mobile Server onBoard Server(VMS.onBoard Server) which is an in-flight mobile cloud server), c)synchronizing said VMS.onBoard Server with OWA.VMS on Ground (mainMobile Cloud Server) whenever wireless connection is available, viaOWA.Air Transceiver(s) in aircraft, d) offering best-of-effort in-flightapplications and services to users of in-flight community through saidin-flight wireless networks, and wherein, said OWA.onBoard WirelessRouter is turned ON or OFF by In-Flight Pilot Signal, and saidOWA.onBoard Wireless Router is optimized by OWA RTT Optimization.
 2. Themethod as recited in claim 1, wherein said OWA.onBoard RTTs or saidIn-Flight RTTs comprise: a) standard wireless local area network (WLAN)with reduced and lowest possible transmitting power for airbornein-flight connection, fully monitored and controlled at all times bysaid OWA.onBoard Wireless Router to avoid frequency interference withany aviation communication and navigation systems, b) modified wirelesslocal area network for airborne in-flight connection (WLAN.Air) which iscompletely in compliance with the airborne communication regulations andguidelines, c) standard wireless personal access network or personalarea network (WPAN) with reduced and lowest possible transmitting powerfor airborne in-flight connection, fully monitored and controlled at alltimes by said OWA.onBoard Wireless Router to avoid frequencyinterference with any aviation communication and navigation systems, andd) modified wireless personal access network or personal area networkfor airborne in-flight connection (WPAN.Air) which is completely incompliance with the airborne communication regulations and guidelines.3. The method as recited in claim 1 wherein said OWA Mobile Device (orOWA-enabled Mobile Device) connecting to said OWA.onBoard WirelessRouter for In-Flight mode, said method comprising: a) said OWA MobileDevice immediately turning off all of its terrestrial radio transceiversand switching to said In-Flight mode automatically when receiving anIn-Flight Pilot Signal of the aircraft through a separate in-flightbroadcasting channel in the aircraft cabins, b) said OWA Mobile Devicebeing connected to said OWA.onBoard Wireless Router through saidIn-Flight RTTs, and c) said OWA Mobile Device being synchronized to saidVMS.onBoard Server, and being able to push any information, contents orapplications to said VMS.onBoard Server or retrieve any information,contents or applications from said VMS.onBoard Server.
 4. The method asrecited in claim 1, wherein said OWA RTT Optimization comprises: a) saidOWA Mobile Device (or OWA-enabled Mobile Device) remaining inTerrestrial mode with Ground networks if said OWA Mobile Device notreceiving said In-Flight Pilot Signal in aircraft cabins, b) said OWAMobile Device immediately turning off its terrestrial radiotransceivers, switching to said In-Flight Mode accordingly afterreceiving said In-Flight Pilot Signal in aircraft cabins, and said OWAMobile Device becoming an OWA.inFlight Mobile Device for in-flightwireless connection, c) said OWA Mobile Device searching whether saidWLAN.Air RTT is available for said in-flight wireless networks, and saidOWA Mobile Device being connected in said WLAN.Air connection mode ifsaid WLAN.Air RTT is available, otherwise, said OWA Mobile Devicefurther searching whether said WPAN.Air RTT is available for saidin-flight wireless networks, and said OWA Mobile Device being connectedin said WPAN.Air connection mode if said WPAN.Air RTT is available, d)said OWA Mobile Device further searching said WLAN RTT or said WPAN RTTif both said WLAN.Air RTT and said WPAN.Air RTT are not available forsaid in-flight wireless networks, and said OWA Mobile Device firstreducing its radio transmitting power to the minimal level, thenconnecting to said in-flight wireless networks in said WLAN or said WPANconnection mode if either said WLAN RTT or said WPAN RTT is available,and e) said OWA Mobile Device also supporting wireline connection modeby plugging into said OWA.onBoard Wireless Router through a networkingcable or other forms of wiring in the aircraft.
 5. The method as recitedin claim 4, wherein search order of connection modes between said OWAMobile Device and said OWA.onBoard Wireless Router is re-configured orre-set by mobile users or aircrafts wherein by default, said searchorder is by said WLAN.Air, said WPAN.Air, said WLAN, said WPAN and saidwireline connection.
 6. The method as recited in claim 4, wherein saidWLAN.Air and said WPAN.Air are the safest modes for In-Flightconnection, networking and services, completely in compliance withairborne communication regulations and guidelines.
 7. The method asrecited in claim 1 wherein said OWA.Air Transceiver connects to GroundCell(s) of Ground Networks, other said OWA.Air Transceiver in Ad-Hoc ormesh network group, Broadband Satellite Networks, and/or Ground AirportNetworks for Internet Access.
 8. The method as recited in claim 1wherein said in-flight community includes passengers of same flight andneighborhood flights of same said Ad-Hoc or mesh network group.
 9. Themethod as recited in claim 1 wherein said users can push interestingapplications, services and contents to said VMS.onBoard Server forsharing with other said users, and said users can pop interestingapplications, services and contents shared by other said users from saidVMS.onBoard Server.
 10. The method as recited in claim 1 wherein saidVMS.onBoard Server is an in-flight mobile cloud server, extended fromsaid OWA.VMS which is a main mobile cloud server on ground.
 11. Themethod as recited in claim 1 wherein said in-flight applications andservices comprise: a) in-flight social networking, b) in-flight videosharing, c) in-flight business conferencing, d) in-flight interactivegaming, e) in-flight shopping mall, f) in-flight audio and videolibrary, g) in-flight safety and security, h) in-flight VIP (veryimportant person) services, and wherein, said in-flight socialnetworking service and application includes displaying and updating ofelements of passenger's photo, seat number, nickname and content windowscomprising messaging, posting, pictures and videos, as well as linkingto or synchronizing with passenger's terrestrial social networkingplatforms including Facebook, LinkedIN and Google plus.
 12. The methodas recited in claim 1 wherein said OWA-enabled Mobile Device is anexisting mobile device with external OWA module attached to saidexisting mobile device wherein said external OWA module facilitatescompletely switching from said terrestrial mode to said in-flight modeby said In-Flight Pilot Signal, and completely turning off saidterrestrial radio transceiver in said in-flight mode, and said externalOWA module further enables said existing mobile device to fully supportsaid In-Flight RTTs including said WLAN.Air, said WPAN.Air, said WLANand said WPAN.
 13. The method as recited in claim 1 wherein saidIn-Flight Pilot Signal remains ON and continues broadcasting to all saidOWA Mobile Devices in said aircraft cabins to maintain said In-Flightmode as long as said aircraft leaves airport Gate (in flight, taxing,taking-off, landing), and said In-Flight Pilot Signal can be turned offonly after said aircraft returns to and stops completely at airport Gateto enable said OWA Mobile Device switch back to said Terrestrial Modewith said ground network, wherein the time to release or turn-off saidIn-Flight Pilot Signal may vary based on different airborne regulationsand rulings in different regions, and in most situations, said In-FlightPilot Signal is turned off only after said aircrafts return to AirportGates.
 14. The method as recited in claim 1 wherein said In-Flight PilotSignal will automatically switch said OWA Mobile Device from saidTerrestrial mode to said In-Flight mode completely, so that said OWAMobile Device does not have to power off or manually switch to saidin-flight mode when on board said aircrafts.
 15. The method as recitedin claim 1 wherein said VMS.onBoard Server is also utilized to be avirtual secretary for mobile user with said OWA Mobile Device in saidIn-Flight mode, and multiple said OWA Mobile Devices can share same saidVMS.onBoard Server.
 16. The method as recited in claim 1 wherein saidOWA Mobile Device allows allocating multiple air interfaces into anexternal air interface card and mobile users change wireless standardsby updating said air interface card without having to change said OWAmobile device.
 17. The method as recited in claim 1 wherein each saidOWA.Air Transceiver is capable to support one or multiple connections toeither said OWA.Ground Transceiver, said ground network, said groundairport network, said broadband Satellite network, or to other saidOWA.Air Transceiver in other aircraft of said ad-hoc or mesh networkgroup.
 18. The method as recited in claim 1 wherein each aircraft isequipped with one or multiple said OWA.Air Transceivers for constructingbroadband unified airborne and terrestrial networks for high-qualityin-flight applications and services.
 19. The method as recited in claim12 wherein said external OWA module can be in the form of memory card,USB (Universal Serial Bus) card, any portable interface card, or beingembedded in or integrated into a protection case of said existing mobiledevice.
 20. The method as recited in claim 12 wherein said external OWAmodule has functions of turning off terrestrial cellular radiotransceiver of said existing mobile device and controlling transceiversof WLAN and WPAN in said existing mobile device to meet systemrequirements of said In-Flight RTTs including said WLAN.Air, saidWPAN.Air, said WLAN and said WPAN.